Control of Nitrogen Oxides Dr. Wesam Al Madhoun

Specific sources of NO x Combustion sources Automobiles Boilers Incinerators High-temperature industrial operations Metallurgical furnaces Blast furnaces Kilns Other sources Industrial processes that use nitric acid

US sources of NOx

It’s one of the main ingredients involved in the formation of ground-level ozone, which can trigger serious respiratory problems reacts to form nitrate particles, acid aerosols, as well as NO 2, which also cause respiratory problems contributes to formation of acid rain contributes to nutrient overload that deteriorates water quality contributes to atmospheric particles that cause visibility impairment. contributes to global warming NO x effects

Characteristics of NO x compounds NO – Nitric oxide Colorless and odorless gas Insoluble in water (Remember this for later on!) Toxic NO 2 – Nitrogen dioxide Has distinct reddish-brown color Moderately soluble in aqueous liquids Toxic Contributes to brown haze that occurs with smog

NO x Regulation Q.NOx concentrations are relatively low in the atmosphere, so why are they regulated? NO and NO 2 react rapidly with other compounds, creating ozone and other undesirable compounds. The NO and NO 2 may never reach high concentrations, but are creating other air pollutants.

NO x Formation Formed at elevated temperatures during combustion of fuel in the presence of air. Approximately 90 to 95% of the nitrogen oxides generated in combustion processes are in the form of nitric oxide (NO). (Remember this for later on!) Once in the atmosphere, the NO reacts in a variety of photochemical and thermal reactions to form NO 2.

Thermal NOx: formed by reaction between N 2 and O 2 in the air; sensitive to temperature Fuel NOx: formed from combustion of fuel containing organic nitrogen; dependent on local combustion conditions and nitrogen content in the fuel. Not all of the fuel nitrogen compounds are released during combustion. Unlike sulfur, a significant fraction of the fuel nitrogen remains in the bottom ash or in the fly ash. NO x Formation

NO x Control Technologies

Control Techniques 1. Modify combustion to suppress NO x formation Low excess air operation Off-stoichiometric combustion Flue gas recirculation 2.Reduce NO x to molecular nitrogen through controls (also known as flue gas treatment) Selective Non-Catalytic Reduction (SNCR) Selective Catalytic Reduction (SCR)

Combustion Modifications Low excess air operation: Involves a reduction in the total quantity of air used in the combustion process. By using less oxygen, the amount of NOx produced is not as great.

Combustion Modifications Off-stoichiometric combustion: Involves the mixing of the fuel and air in a way that reduces the peak gas temperatures and peak oxygen concentrations.  A portion of the combustion flame is operated with very low oxygen levels (fuel rich) to allow a major portion of the fuel oxidation to occur under conditions where NO x formation is suppressed.  Combustion is completed in the remaining portion of the flame and/or combustion chamber by providing the remainder of the oxygen needed for complete fuel oxidation.

 Low NOx burners: Keeps temperatures down and dissipates heat quickly  Over-fire air (OFA): Keeps mixture fuel rich and completes combustion process using air injection nozzles  Burners out of service (BOOS): Operates alternate burners in combustion zone as fuel rich, air rich, and air only

Flue gas recirculation  Involves the return of cooled combustion gases to the burner area of the boiler.  Reduced temperatures produce less NOx.  The process requires a recirculation fan and duct system. Combustion Modifications

Fuel re-burning: Involves the operation of the main burners in a boiler at very low excess air (fuel rich conditions). Between 10 to 20% of the total fuel is injected into the boiler through a series of ports. This creates fuel rich conditions across the entire combustion chamber. The partially oxidized compounds formed in the burner and reburn fuel injection area, which is located in the middle region of the boiler, are then oxidized completely in the upper region of the boiler.

 A series of over-fire air ports are used in this upper region to provide all of the air needed for complete combustion.

Add-On Controls (Flue Gas Treatment ) Selective non-catalytic reduction systems (SNCR)  Involves the injection of ammonia (NH 3 ) or urea into the hot gas zone where reactions leading to reduction of nitrogen oxides can occur.  The reactions are completed within the boiler, and no waste products are generated.  There is a risk of ammonia (NH 3 ) being emitted into the atmosphere if temperatures are too low, however.  SCNR systems are capable of reducing nitrogen oxides from 20 to 60%.

Selective Non-catalytic Reduction (SNCR) Reactions: Add-On Controls (Flue Gas Treatment ) Above 1000 o C

Selective catalytic reduction (SCR)  Involves using beds containing ammonia or urea to reduce nitrogen oxides to molecular nitrogen and water.  Two or three catalysts (usually tungsten and vanadium) are arranged in the beds so air can flow through.  NOx reduction efficiencies ranging from 75 to 90% are possible when the amount of catalyst is sufficient, the catalyst is in good condition,  the ammonia reagent flow is sufficient, and the ammonia is adequately distributed across the gas stream. Add-On Controls (Flue Gas Treatment )

Selective Catalytic Reduction (SCR) Reactions Temperature ~ o C

 Wet scrubbers would not be a good control technique for NO x emissions.  Why? Remember, NO is mainly formed during the combustion process and NO 2 is formed in the atmosphere.  Since NO is insoluble in water, wet scrubbing would not work very well! Final Remark